import numpy as np
from scipy.signal import fftconvolve

def bkfilter(X, low=6, high=32, K=12):
    """
    Baxter-King bandpass filter

    Parameters
    ----------
    X : array-like
        A 1 or 2d ndarray. If 2d, variables are assumed to be in columns.
    low : float
        Minimum period for oscillations, ie., Baxter and King suggest that
        the Burns-Mitchell U.S. business cycle has 6 for quarterly data and
        1.5 for annual data.
    high : float
        Maximum period for oscillations BK suggest that the U.S.
        business cycle has 32 for quarterly data and 8 for annual data.
    K : int
        Lead-lag length of the filter. Baxter and King propose a truncation
        length of 12 for quarterly data and 3 for annual data.

    Returns
    -------
    Y : array
        Cyclical component of X

    References
    ---------- ::
    Baxter, M. and R. G. King. "Measuring Business Cycles: Approximate
        Band-Pass Filters for Economic Time Series." *Review of Economics and
        Statistics*, 1999, 81(4), 575-593.

    Notes
    -----
    Returns a centered weighted moving average of the original series. Where
    the weights a[j] are computed ::

      a[j] = b[j] + theta, for j = 0, +/-1, +/-2, ... +/- K
      b[0] = (omega_2 - omega_1)/pi
      b[j] = 1/(pi*j)(sin(omega_2*j)-sin(omega_1*j), for j = +/-1, +/-2,...

    and theta is a normalizing constant ::

      theta = -sum(b)/(2K+1)

    Examples
    --------
    >>> import gwstatsmodels.api as sm
    >>> dta = sm.datasets.macrodata.load()
    >>> X = dta.data['realinv']
    >>> Y = sm.tsa.filters.bkfilter(X, 6, 24, 12)
    """
#TODO: change the docstring to ..math::?
#TODO: allow windowing functions to correct for Gibb's Phenomenon?
# adjust bweights (symmetrically) by below before demeaning
# Lancosz Sigma Factors np.sinc(2*j/(2.*K+1))
    if low < 2:
        raise ValueError("low cannot be less than 2")
    X = np.asarray(X)
    omega_1 = 2.*np.pi/high # convert from freq. to periodicity
    omega_2 = 2.*np.pi/low
    bweights = np.zeros(2*K+1)
    bweights[K] = (omega_2 - omega_1)/np.pi # weight at zero freq.
    j = np.arange(1,int(K)+1)
    weights = 1/(np.pi*j)*(np.sin(omega_2*j)-np.sin(omega_1*j))
    bweights[K+j] = weights # j is an idx
    bweights[:K] = weights[::-1] # make symmetric weights
    bweights -= bweights.mean() # make sure weights sum to zero
    if X.ndim == 2:
        bweights = bweights[:,None]
    return fftconvolve(bweights, X, mode='valid') # get a centered moving avg/
                                                  # convolution
